Method and system for fibre channel arbitrated loop acceleration

ABSTRACT

A fibre channel switch element with an acceleration device that connects plural fibre channel devices in an arbitrated loop and monitors frames sent during a loop initialization process is provided. The acceleration device creates an AL_PA table selected by each fibre channel device, wherein the AL_PA table is used for port selection; and during an arbitration process sends a benign primitive to non-arbitrating devices. The acceleration device includes, a global arbitration module, a state machine module, and a matrix for connecting plural fibre channel devices.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority under 35 USC Section 119(e), to the following provisional patent applications:

-   -   Ser. No. 60/487,876 filed on Jul. 16, 2003;     -   Ser. No. 60/487,887 filed on Jul. 16, 2003;     -   Ser. No. 60/487,875 filed on Jul. 16, 2003;     -   Ser. No. 60/490,747 filed on Jul. 29, 2003;     -   Ser. No. 60/487,667 filed on Jul. 16, 2003;     -   Ser. No. 60/487,665 filed on Jul. 16, 2003;     -   Ser. No. 60/492,346 filed on Aug. 4, 2003; and     -   Ser. No. 60/487,873 filed on Jul. 16, 2003.

BACKGROUND

The disclosures of the foregoing applications are incorporated herein by reference in their entirety.

1. Field of the Invention

The present invention relates to networks, and more particularly, to reducing latency in a fibre channel arbitrated loop environment.

2. Background of the Invention

Fibre channel is a set of American National Standard Institute (ANSI) standards, which provides a serial transmission protocol for storage and network protocols such as HIPPI, SCSI, IP, ATM and others. Fibre channel provides an input/output interface to meet the requirements of both channel and network users.

Fibre channel supports three different topologies: point-to-point, arbitrated loop and fibre channel fabric. The point-to-point topology attaches two devices directly. The arbitrated loop topology attaches devices in a loop. The fibre channel fabric topology attaches host systems directly to a fabric, which are then connected to multiple devices. The fibre channel fabric topology allows several media types to be interconnected.

Fibre channel is a closed system that relies on multiple ports to exchange information on attributes and characteristics to determine if the ports can operate together. If the ports can work together, they define the criteria under which they communicate.

In fibre channel, a path is established between two nodes where the path's primary task is to transport data from one point to another at high speed with low latency, performing only simple error detection in hardware.

FC-AL is one fibre channel standard (incorporated herein by reference in its entirety) that establishes the protocols for an arbitrated loop topology.

In a Fibre Channel Arbitrated Loop (FC-AL) implementation of each device on the loop must have the intelligence to process incoming data in accordance with FC-AL rules. Latency occurs due to every device in the loop, as data is processed. This latency is accumulated around the loop. Even when a device is only required to pass data to the next device, it still has latency before passing on the data, because the device must continuously process data for changes in state. The accumulated latency slows down data transfers in a heavily populated loop.

The traditional FC-AL implementation has a transmitter of one device connected to the receiver of the next device and so on until the transmitter of the last device is connected to the receiver of the first device, creating a loop, as shown in FIG. 2.

In the traditional FC-Al implementation, all fibre channel devices (“FCDs”), to properly follow the FC-AL protocol, need to implement a LPSM. The LPSM has the following states: initializing, open-initiate, monitoring, arbitrating, arbitration won, open, opened, transmitted close, received close, transfer, and old-port (optional) before the FC-AL standard.

Under the FC-AL standard, there can be a maximum of 127 devices on a loop. Every device on the loop must be operating correctly for the loop to be operational. Because of this, many implementations include a bypass element that allows loop connectivity to be maintained when a particular device is not available for proper operation. Standard bypass elements are not intelligent devices and are not controlled based on data being transmitted but on device functionality or availability. These bypass elements do not add latency, but add jitter.

Each connected device must follow the FC-AL standard by decoding primitives, maintaining a Loop Port State Machine (LPSM), obtaining AL_PA's through the LIP process, performing arbitration, and sending frames in a manner that is consistent with the standard.

The following introduces some FC-AL process steps and how these processes add delay/latency:

LIP Process: In the traditional FC-AL implementation, the LIP process is started when one or more of the devices on the loop start sending LIPs to the next device in the loop. After all devices have seen the LIP, a temporary master is selected and this master sends out various frames that each device uses to select an AL_PA. The frames are sent in a serial fashion and the master must get the first frame back before sending the next type of frame. There are several trips around the loop before the LIP process is completed. Each device acquires an AL_PA and only needs to know its own AL_PA to be FC-AL compliant. Thus when all the frames return to the master, all the participating devices have their AL_PA's. The AL_PA's are used for identification and priority evaluation in the arbitration.

Each device in the loop takes time to process incoming data and deciding (per FC-AL standard) what to send out to its transmitter. Thus each device adds to latency and slows data processing. Two major points of latency are the time delay to create (and close) the loop circuit and the time delay for frames to be passed back and forth. To create a loop circuit in a traditional implementation the device must arbitrate for access and then open the device.

Arbitration process: In the traditional FC-AL implementation, the device desiring access to the loop does arbitration. In order to arbitrate and win arbitration, the device must send arbitration primitives and receive the arbitration primitive back.

In the simplest case, only one device wants access. The device that wants access to the loop sends its arbitration primitive to the next device in the loop and after some processing the next device passes the arbitration primitive onto the next device and so on until the primitive returns to the originating device. Therefore, for the FCD to know it has won arbitration there is an entire loop delay, even if it is the only device that wants access to the loop.

Open process: In the traditional FC-AL implementation to complete a loop circuit, the winning device needs to open the device it wants to communicate with. To open the other device and know that it is open (using zero BB_Credit) the device sends an open primitive and receives back an R_RDY primitive. The open primitive (OPN) is sent by the winning device to the next device, which processes it and sends it on to the next device and so on until the destination device receives the open primitive. Then the destination FCD sends a R_RDY primitive to the next device it is connected to and that device processes the primitive and sends it to the next device and so on, until the R_RDY primitive reaches the winning FCD. Thus to open the loop circuit and to know it is open, causes a delay around the loop.

“Open Replicate” process: In the traditional FC-AL implementation, to complete the loop circuit a winning FCD can send an open replicate primitive(s). When the winning FCD does a broadcast open replicate then every FCD will replicate the incoming frames and send them out to the next device. When the winning FCD does a specific open replicate then it sends out a number of open replicate primitives to inform the FCDs (that it wants to communicate) to replicate the frames on the incoming port and also send the frame on to the next device. There are no R_RDY primitives sent for an open replicate primitive, so frames can quickly follow the open primitive(s), but there is still delay to pass the frames around the entire loop.

Close process: In the traditional implementation to close the loop circuit, active devices must send a close primitive to the other device. An entire loop delay occurs when one of the devices sends a close primitive that is received by the other device before it sends its close primitive. Once the first device receives the second close primitive then the loop circuit is closed. Per the FC-AL standard, it is not required for the close primitives to be sent in a serial fashion, hence, the close primitives can be traveling the loop at the same time affecting the overall latency.

The following summarizes, the problems with traditional FC-AL implementation:

Problem 1: Large latency in loop communication implementations.

Problem 2: Separate devices to bypass non-working devices add cost to overall system and add jitter to the communication network.

Problem 3: Since only a device needs to know its AL_PA in a conventional standard system, there is no required “system” for determining the AL_PAs used in a loop.

Problem 4: Conventional methodology does not support global arbitration.

Problem 5: All devices on a loop currently need to support a full LPSM, and hence can be expensive.

Problem 6: The open replicate feature of the FC-AL has a long latency on frames sent because all frames need to return to the source device to be removed from the loop.

Therefore, what is required is a process and system that can accelerate frame processing and minimize latency in fibre channel arbitrated loop topology.

SUMMARY OF THE INVENTION

In one aspect of the present invention, a fibre channel switch element is provided. The switch element includes, an acceleration device that connects plural fibre channel devices in an arbitrated loop and monitors frames sent during a loop initialization process and creates an AL_PA table selected by each fibre channel device, wherein the AL_PA table is used for port selection; and during an arbitration process sends a benign primitive to non-arbitrating devices.

During an open process, the acceleration device connects a fibre channel device that wins arbitration to a destination device so that an open primitive can be sent directly to the destination device. Non-destination devices receive a benign primitive during the open process to maintain proper loop state machine state.

During an open replicate process, the acceleration device after it receives an open replicate primitive creates a spray pattern for all ports with which a fibre channel device intends to communicate.

In yet another aspect of the present invention, an acceleration device used by a fibre channel switch element is provided. The acceleration device includes, a global arbitration module, a state machine module, and a matrix for connecting plural fibre channel devices; wherein the acceleration device connects plural fibre channel devices in an arbitrated loop and monitors frames sent during a loop initialization process and creates an AL_PA table selected by each fibre channel device, wherein the AL_PA table is used for port selection; and during an arbitration process sends a benign primitive to non-arbitrating devices.

In yet another aspect of the present invention, a method for accelerating traffic in a fibre channel arbitrated loop topology having a fibre channel switch element with an acceleration device is provided. The method includes, monitoring fibre channel frames during a loop initialization process; creating an AL_PA table for fibre channel devices connected in the arbitrated loop and using the AL_PA table for identifying ports. The method also includes, sending benign primitives to non-arbitrating devices during an arbitration process; connecting a fibre channel device that sends an OPEN primitive to a destination port; and sending a benign primitive to non-destination device connected in the arbitrated loop.

The method also includes creating a spray pattern after receiving an open replicate primitive from a fibre channel device; and sending frames to plural destination ports at the same time.

This brief summary has been provided so that the nature of the invention may be understood quickly. A more complete understanding of the invention can be obtained by reference to the following detailed description of the preferred embodiments thereof concerning the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing features and other features of the present invention will now be described with reference to the drawings of a preferred embodiment. In the drawings, the same components have the same reference numerals. The illustrated embodiment is intended to illustrate, but not to limit the invention. The drawings include the following Figures:

FIG. 1 shows a block diagram of a storage area network;

FIGS. 2 and 3 show configurations that use the adaptive aspects of the present invention;

FIG. 4 shows a block diagram of a switch element, according to one aspect of the present invention;

FIGS. 5A and 5B (jointly referred to as FIG. 5) show a block diagram of a transmission protocol engine, according to one aspect of the present invention;

FIGS. 6A and 6B show block diagrams for a diagnostic module and a SES module, according to one aspect of the present invention;

FIG. 7 shows a block diagram of acceleration device, according to one aspect of the present invention;

FIG. 8 shows an example of how plural fibre channel switch elements may be used to couple 127 fibre channel devices, according to one aspect of the present invention; and

FIGS. 9A and 9B show a state machine for the acceleration device, according to one aspect of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Definitions:

The following definitions are provided as they are typically (but not exclusively) used in the fibre channel environment, implementing the various adaptive aspects of the present invention.

“Active device”: The source device (winning arbitrator) or the destination device.

“Active port”: A port with an active device attached to it.

“AL_PA”: Arbitrated loop physical address.

“BB_Credit”: Buffer-to-Buffer Credit

“FCD”: Fibre Channel device

“FC-AL”: Fibre channel arbitrated loop process described in FC-AL standard.

“Fibre channel ANSI Standard”: The standard (incorporated herein by reference in its entirety) describes the physical interface, transmission and signaling protocol of a high performance serial link for support of other high level protocols associated with IPI, SCSI, IP, ATM and others.

“FC-1”: Fibre channel transmission protocol, which includes serial encoding, decoding and error control.

“FC-2”: Fibre channel signaling protocol that includes frame structure and byte sequences.

“FC-3”: Defines a set of fibre channel services that are common across plural ports of a node.

“FC-4”: Provides mapping between lower levels of fibre channel, IPI and SCSI command sets, HIPPI data framing, IP and other upper level protocols.

“LIP”: Loop initialization protocol primitive.

“L_Port”: A port that contains Arbitrated Loop functions associated with the Arbitrated Loop topology.

“SES”: SCSI Enclosure Services.

“TPE”: Transmission Protocol Engine, a controller that operates at the FC-1 level.

To facilitate an understanding of the preferred embodiment, the general architecture and operation of a fibre channel system will be described. The specific architecture and operation of the preferred embodiment will then be described with reference to the general architecture of the fibre channel system.

FIG. 1 is a block diagram of a fibre channel system 100 implementing the methods and systems in accordance with the adaptive aspects of the present invention. System 100 includes plural devices that are interconnected. Each device includes one or more ports, classified as node ports (N_Ports), fabric ports (F_Ports), and expansion ports (E_Ports). Node ports may be located in a node device, e.g. server 103, disk array 105 and storage device 104. Fabric ports are located in fabric devices such as switch 101 and 102. Arbitrated loop 106 may be operationally coupled to switch 101 using arbitrated loop ports (FL_Ports).

The devices of FIG. 1 are operationally coupled via “links” or “paths”. A path may be established between two N_ports, e.g. between server 103 and storage 104. A packet-switched path may be established using multiple links, e.g. an N-Port in server 103 may establish a path with disk array 105 through switch 102.

In one aspect of the present invention, an acceleration method and system is provided that maintains FC-AL operation while reducing the overall latency as compared to standard FC-AL implementations.

FIG. 4 is a block diagram of an 18-port ASIC FC element 400A (also referred to as system 307) according to one aspect of the present invention. FC element 400A provides various functionality in an FC-AL environment, including without limitation, FC element 400A operates as a loop controller and loop switch using switch matrix 408, in accordance with the FC-AL standard.

FC element 307 of the present invention is presently implemented as a single CMOS ASIC, and for this reason the term “FC element” and ASIC are used interchangeably to refer to the preferred embodiments in this specification. Although FIG. 4 shows 18 ports, the present invention is not limited to any particular number of ports.

System 307 provides a set of port control functions, status indications, and statistics counters for monitoring the health of the loop and attached devices, diagnosing faults, and recovering from errors.

ASIC 307 has 18 ports where 16 ports are shown as numeral 405 while a host port 404 and cascade port 404A are shown separately for convenience only. These ports are generic to common Fibre Channel port types, for example, L_Ports.

For illustration purposes only, all ports are drawn on the same side of ASIC 307 in FIG. 4. However, the ports may be located on any side of ASIC 307. This does not imply any difference in port or ASIC design. Actual physical layout of the ports will depend on the physical layout of the ASIC.

Each port has transmit and receive connections to switch matrix 408 and includes transmit protocol engine 407 and a serial/deserializer 406. Frames enter/leave the link 405A and SERDES 406 converts data into 10-bit parallel data to fibre channel characters.

Switch matrix 408 dynamically establishes a connection for loop traffic. Switch matrix 408 includes a global arbiter (hence switch matrix 408 is also referred to as SGA 408) that provides lower latency and improved diagnostic capabilities while maintaining full Fibre Channel Arbitrated Loop (FC-AL) compliance.

Switch matrix 408 is also referred to as an acceleration device 408 throughout this specification. All transmitters and receivers of all devices are connected to the acceleration device 408, as shown in FIG. 3. Any device that is not operating properly is isolated, which means that acceleration device 408 also acts as a virtual bypass element for each FCD. Each FCD connected to the acceleration device 408 operates in the same fashion as in the traditional implementation, per the FC-AL standard.

FIG. 7 shows a block diagram of acceleration device 408 and it includes an AL_PA table 408C, a state machine 408D, a global arbiter 408B, a controller 408F, and data switching paths 408A. Devices are coupled via matrix 408E through connection 408A. State machine 408D states are described below with respect to FIG. 9.

Global arbiter 408B selects the arbitration winner from all arbitrating channels according to FC-AL rules. For switch channels that request arbitration at a given time, the AL_PA is looked up in table 408C to validate an arbitration request. This is because a switch channel may be repeating an arbitration primitive that it received and may not be requesting arbitration for itself.

Arbiter 408B has a validation and comparison section (not shown). The validation section includes combinatorial logic that validates an arbitration request (“cARBDet”) for a given switch channel. The comparison section includes comparators and multiplexers that output the highest arbitrating switch channel.

Controller 408F has three modes of operation, loop mode, spray mode and connection mode. In the loop mode, an isolated switch channel receives data from a previous un-isolated switch channel, however data from the isolated switch channel (or port) is not sent to the loop.

In the spray mode, again an isolated switch channel receives spray elements from a previous un-isolated switch channel, however data from the isolated switch channel (or port) is not sent to the loop. Controller 408F is in spray mode when there is no active traffic for the loop and data is sprayed from a host port to the transmit sections of other switch channels.

In the connection mode, isolated switch channels receive ARB(F0), however data from the isolated switch channel (or port) is not sent to the loop. Controller 408F is in connection mode when there is active traffic for the loop.

Switch matrix 408 provides a quasi-direct architecture in the form of a buffer-less Switch Matrix. Switch matrix 408 includes data multiplexers that provide a path to each port. In one aspect, twenty multiplexers may be used. In one aspect, data is 16 bits wide plus the internal “K” control signal and two parity bits.

At power-up, SGA 408 is setup in a flow-through configuration, which means all ports send what was received on host port 404. When a valid LIP sequence occurs, SGA 408 configures the switch to a complete loop configuration for the address selection process. During normal data transfer on the loop, SGA 408 reconfigures the switch data-path to connect the active ports in what appears as a smaller loop, which lowers the latency but still emulates FC-AL functionality to all entities on the loop.

During loop configuration, SGA 408 configures the switch data-path to include a snooping port that walks through each port during the LIP physical address assignment to track each port's assigned arbitrated loop physical address (AL_PA). This snooping process is called the ‘LIP walk’. When the LIP process is done, the firmware records the “port to AL_PA” map in an internal table built in SGA 408. During normal data transfer mode, SGA 408 monitors arbitration requests, open requests, and close primitives to determine which ports have traffic that must be forwarded. The ports that have traffic for the loop provide the necessary information to create the connection points for the switch data-path. The inactive ports are provided the primitive ARB(F0).

SGA 408 selects the arbitration winner, from all the arbitrating ports, according to Fibre Channel Arbitrated Loop (FC-AL) rules. For ports, which detect arbitration, the AL_PA is looked up in a Port Address Table to see if the arbitration request is valid for that port. Due to the unique purpose of port 0 (Host port 404), port 0 never needs to win arbitration, but can detect that the arbitration winner is outside a range, or with ARB(F0)/IDLE show that devices outside system 307 are not arbitrating at a given time.

For arbitration detect on host port 404 to be considered valid the “ArbPS0” cannot match an AL_PA in the internal Port Address Table, which means that the source address is not in a particular system 307. For ports seeking a valid arbitration, the AL_PA determines which arbitrating device has highest priority; and typically, the port with the lowest AL_PA value is always selected as the winner.

SGA 408 creates a direct loop connection between source and destination devices. This connection methodology avoids the delay associated with data having to pass from one disk drive member of the loop to the next until the data has completed traversing the loop. In one aspect, the following formula evaluates performance of a loop connection: Latency (word times)=n*(2*8)+disk+host=16n+12

Where n is the number of systems 307 that comprise the FC loop, 6 is the latency of the disk drive that is part of the loop connection and 6 is typically the latency of the attached host.

System 307 includes plural 12C (12C standard compliant) interfaces 412-413 that allow system 307 to couple to plural 12C ports each having a master and slave capability.

System 307 also includes a general-purpose input/output interface (“GPIO”) 415. This allows information from system 307 to be analyzed by any device that can use GPIO 415. Control/Status information 419 can be sent or received through module 415. Timer module 411 is provided to control various timer operations.

System 307 also includes a SPI module 414 that is used for parallel to serial and serial to parallel transfer between processor 400 firmware and flash memory 421 in the standard Little Endian format.

System 307 also includes a Universal Asynchronous Receiver/Transmitter (“UART”) interface 418 that converts serial data to parallel data (for example, from a peripheral device modem or data set) and vice-versa (data received from processor 400) complying industry standard requirements.

System 307 can also process tachometer inputs (received from a fan, not shown) using module 417. Processor 400 can read the tachometer input via a tachometer rate register and status register (not shown).

System 307 provides pulse width modulator (“PWM”) outputs via module 416. Processor 400 can program plural outputs.

System 307 also includes two frame manager modules 402 and 403 that are similar in structure. Processor 400 can access runtime code from memory 420 and input/output instructions from read only memory 409.

Module 402 (also referred to as the “diag module 402”) is a diagnostic module used to transfer diagnostic information between a FC-AL and the firmware of system 307.

Diag module 402 is functionally coupled to storage media (via ports 405) via dedicated paths outside switch matrix 408 so that its connection does not disrupt the overall loop. Diag module 402 is used for AL_PA capture during LIP propagation, drive(s) (coupled to ports 405) diagnostics and frame capture.

Module 403 (also referred to as “SES module 403”) complies with the SES standard and is functionally coupled to host port 404 and its output is routed through switch matrix 408. SES module 403 is used for in-band management services using the standard SES protocol.

When not bypassed, modules 402 and 403 receive primitives, primitive sequences, and frames. Based on the received traffic and the requests from firmware, modules 402 and 403 maintain loop port state machine (LPSM) (615, FIG. 6B) in the correct state per the FC-AL standard specification, and also maintain the current fill word.

Based on a current LPSM 615 state (OPEN or OPENED State), modules 402 and 403 receive frames, pass the frame onto a buffer, and alert firmware that a frame has been received. Module 402 and 403 follow FC-AL buffer to buffer credit requirements.

Firmware may request modules 402 and 403 to automatically append SOF and EOF to the outgoing frame, and to automatically calculate the outgoing frame's CRC using CRC generator 612. Modules 402 and 403 can receive any class of frames and firmware may request to send either fibre channel Class 2 or Class 3 frames.

Port Management Interface (PMIF) 401 allows processor 400 access to various port level registers, SerDes modules 406 and TPE Management Interfaces 509 (FIG. 5). PMIF 401 contains a set of global control and status registers, receive and transmit test buffers, and three Serial Control Interface (SCIF) controllers (not shown) for accessing SerDes 406 registers.

FIGS. 6A and 6B show block diagrams for module 402 and 403. It is noteworthy that the structure in FIGS. 6A and 6B can be used for both modules 402 and 403. FIG. 6B is the internal data path of a FC port 601 coupled to modules 402/403.

Modules 402 and 403 interface with processor 400 via an interface 606. Incoming frames to modules 402 and 403 are received from port 601 (which could be any of the ports 404, 404A and 405) and stored in frame buffer 607. Outgoing frames are also stored in frame buffer 607. Modules 402 and 403 have a receive side memory buffer based on “first-in, first-out” principle RX_FIFO, (“FIFO”) 603 and transmit side TX_FIFO FIFO 604 interfacing with a Random access FIFO 605. A receive side FIFO 603 signals to firmware when incoming frame(s) are received. A transmit side FIFO 604 signals to hardware when outgoing frames(s) are ready for transmission. A frame buffer 607 is used to stage outgoing frames and to store incoming frames. Modules 602 and 602A are used to manage frame traffic from port 601 to buffers 603 and 604, respectively.

Modules 402 and 403 use various general-purpose registers 608 for managing control, status and timing information.

Based on the AL_PA, modules 402 and 403 monitor received frames and if a frame is received for a particular module (402 or 403), it will pass the frame onto a receive buffer and alert the firmware that a frame has been received via a receive side FIFO 603. Modules 402 and 403 follow the FC-AL buffer-to-buffer credit requirements using module 616. Modules 402 and 403 transmit primitives and frames based on FC-AL rules. On request, modules 402 and 403 may automatically generate SOF and EOF during frame transmission (using module 613). On request, modules 402 and 403 may also automatically calculate the Cyclic Redundancy Code (CRC) during frame transmission, using module 612.

Overall transmission control is performed by module 611 that receives data, SOF, EOF and CRC. Transmit Buffer control is performed by module 614. A word assembler module 609 is used to assemble incoming words, and a fill word module 610 receives data “words” before sending it to module 611 for transmission.

FIG. 5 shows a block diagram of the transmission protocol engine (“TPE”) 407. TPE 407 maintains plural counters/registers to interact with drives coupled to ports 405. Each TPE 407 interacts with processor 400 via port manager interface 401.

Each Fibre Channel port of system 400A includes a TPE module for interfacing with SerDes 406. TPE 407 handles most of the FC-1 layer (transmission protocol) functions, including 10B receive character alignment, 8B/10B encode/decode, 32-bit receive word synchronization, and elasticity buffer management for word re-timing and TX/RX frequency compensation.

SerDes modules 406 handle the FC-1 serialization and de-serialization functions. Each SerDes 406 port consists of an independent transmit and receive node.

TPE 407 has a receive module 500 (that operates in the Rx clock domain 503) and a transmit module 501. Data 502 is received from SERDES 406 and decoded by decoding module 504. A parity generator module 505 generates parity data. SGA interface 508 allows TPE to communicate with switch 514 or switch matrix 408. Interface 508 (via multiplexer 507) receives information from a receiver module 506 that receives decoded data from decode module 504 and parity data from module 505.

Management interfaces module 509 interfaces with processor 400. Transmit module 501 includes a parity checker 511, a transmitter 510 and an encoder 512 that encodes 8-bit data into 10-bit data. 10-bit transmit data is sent to SERDES 406 via multiplexer 513.

Port Management Interface (PMIF) 401 allows processor 400 access to various port level registers, SerDes modules 406 and TPE Management Interfaces 509 (MIFs). PMIF 401 contains a set of global control and status registers, receive and transmit test buffers, and three Serial Control Interface (SCIF) controllers (not shown) for accessing SerDes 406 registers.

The following provides a description of various standard FC-AL processes that are accelerated, using system 307 (and acceleration device 408), according to one aspect of the present invention (also referred to as the “accelerated implementation”).

LIP Process: During the LIP process, acceleration device 408 connects all devices as if they were in a loop and the devices behave as in the traditional implementation. In one aspect of the present invention, acceleration device 408 monitors the frames sent during the LIP process to determine the AL_PAs selected by each FCD. A FC-AL compliant entity advances through the loop to intercept the initialization frames from each device for processing before passing them on to the next device. This retrieves the AL_PA selected by each device and creates a table for the AL_PAs of the FCDs connected to system 307. The AL-PA table 408C is then used for identification purposes for port selection.

Arbitration process: In the accelerated implementation (i.e. with acceleration device 408) when the loop is idle, “host” port 404 sends data to all the connected FCDs. When only one device wants access to the loop, the global arbiter 408B connects “host” port 404 to the FCD arbitrating and then connects this FCD back to the “host” port 404. The other FCDs receive a benign primitive, so if they desire to access the loop they can start the arbitration process just as they would in a traditional implementation.

Global arbiter 408B follows the FC-AL rules for arbitration and changes the winning port if a higher priority port starts arbitrating before any existing arbiter has won arbitration, just as in the traditional implementation.

In the accelerated implementation, only the arbitrating and “host” port 404 are connected to the loop. Thus, the delay to retrieve the arbitration primitive (win arbitration) is two re-timing delays, one in the acceleration device 408 and the other through the FCD on the host port 404. If the device on host port 404 is the arbitrating device then the delay is one re-timing delay through the acceleration device.

Open process: In the accelerated implementation (i.e. with acceleration device 408) when the winning FCD sends out an open primitive, the acceleration device 408 connects the destination FCD to the winning FCD, looping through host port 404, and the open primitive is directly passed to the destination FCD. The destination FCD can then send the R_RDY primitive, which travels through the acceleration device 408 and the FCD on the host port 404. The other FCDs receive a benign primitive to maintain the proper LPSM state in those devices. In this case, the latency is three re-timing delays, due to the open primitive, the R_RDY primitive and the delay of the FCD on the host port 404.

If the destination port is upstream of the winning port, there are three re-timing delays, two due to the open primitive and one due to the R_RDY primitive. However, if one of the ports is host port 404, then there is only two re-timing delays through the acceleration device 408.

Open replicate process: In the accelerated implementation (i.e. using acceleration device 408) to complete the loop circuit, the winning FCD can send an open replicate primitive(s). The winning FCD can do a broadcast open replicate or a specific open replicate and the acceleration device 408 responds in a similar manner. When the acceleration device 408 sees the open replicate, it creates a spray pattern that includes the FCDs ports that a source (the winning FCD) port wants to communicate with. The frames are sent to all ports at the same time and then returned to the source for removal from the loop, as per the FC-AL standard. Latency is reduced by the frames arriving at all ports at the same time instead of traveling around the entire loop.

Close process: In the accelerated implementation (i.e. using acceleration device 408) since only the active devices are connected there is only re-timing and host port 404 delay to close the circuit.

State Machine: In the accelerated implementation (i.e. using acceleration device 408), all FCDs connected to the acceleration device 408 need a LPSM as in the traditional implementation. However, acceleration device 408, only requires a state machine (408D) that describes the state of the loop, not individual loop ports. This simplified state machine is not a part of the current FC-AL standard. FIG. 9 (i.e. FIGS. 9A and 9B) shows a state machine diagram for acceleration device 408, according to one aspect of the present invention.

FIG. 9 shows eight basic states for state machine 408D. Table I below describes the basic eight states: State Description PWRUP The power up state is the hardware reset State 0 state. TPE 407 uses this time for speed negotiation, before it allows a valid LIP to be indicated to the SGA 408. The only way to exit this state is to have both the Switch Enable bit set and a valid LIP indication. The Switch Enable bit is only evaluated in this state and is set by firmware of system 307. LOINIT This state is used to put the switch (307) in State 1 the loop configuration and to process LISM and Lix A frames. The first switch channel to indicate ARB (F0) during the LISM processing is the Loop Initialization Master (LIM). The Lix A frames are snooped at each switch channel by walking the Diagnostics port 402 through all unisolated switch channels. Firmware is responsible for advancing the Diagnostics port 402. IDLE This state is used when there is no traffic State 2 on the loop. The switch (307) is set in a single spray configuration where the source of the spray is the Host Port 404. ARBING This state is used to connect the highest State 3 arbitrating switch channel to the loop and stays here until the switch channel arbitrating recognizes that it has won arbitration. ARB WON This state is used to wait for an open State 4 primitive once an arbitrating switch channel has declared it has won arbitration. OPEN This state indicates that an OPEN (OPN) State 5 connection exists. CLEAN This state is used to clear up all State 6 retransmitted closes after Replicated Open. SNDCLS This state is used to send a close primitive State 7 for a connection switch channel that was isolated before it sent a Close (CLS) primitive itself. WTCLS This state is used to wait out the completion State 8 of a connection where one of the connection switch channels was isolated.

Table II below shows the various State Machine 408D transitions, according to one aspect of the present invention: Current State Next State Reason for Transition PWRUP PWRUP When reset occurs, the state machine 408D stays in this state to indicate to the Switch Controller 408F that it should be in default single spray mode. To leave this state is to have a valid LIP occur with the Switch Enable bit set. Loop traffic should NOT be considered reliable until LIPs occur. PWRUP LOINIT When switch 307 is enabled and a valid LIP occurs, the state machine 408 changes to the loop initialization state. Loop traffic at this instance is LIP primitives. Any LOINIT When a valid LIP occurs in any State state, the state machine 408D transitions to the loop initialization state and loop traffic is LIP primitives. LOINIT LOINIT State machine 408D stays in this state until the LIP process has completed. The LOINIT state indicates to the Switch Controller 408F that it should be in loop mode. In loop mode, firmware advances port 402 for snooping AL_PA assignments. Loop traffic consists of LISM and LIxA frames. LOINIT IDLE This transition occurs when the CLS primitive for the LIP process is seen. Only one CLS primitive is used for the LIP process. Loop traffic is CLS and idle primitives. IDLE IDLE When none of the switch channels require active connections to the loop, the state machine 408D stays in the idle state. Loop traffic is idle and possibly link primitives. IDLE ARBING Whenever any switch channel indicates that arbitration primitive has been seen, the state machine 408D changes to the arbitrating state. The Switch Controller 408F makes the winning switch channel, according to the Arbiter module 408B, the source connection for loop traffic and the loop traffic is arbitration primitives. IDLE OPEN Whenever an open primitive has been seen on a previous source port, the state machine 408D changes to the open state. The Switch Controller 408F makes the source of the open primitive to be the current source and the destination of the open primitive to be the destination connection point. Loop traffic is open and idle primitives. ARBING ARBING While a winner is being selected, according to FC-AL protocol a port receives back it's own arbitration primitive to win arbitration, hence, the state machine 408D stays in the arbitrating state. The SrcPN primitive can change during this state and loop traffic is arbitration primitives. ARBING ARBWON When the source switch channel issues an ARB(F0) primitive the state machine 408D changes to the arbitration won state. Loop traffic is arbitration primitives. ARBING OPEN When an open primitive is seen on the source switch channel, the state machine 408D changes to the open state. The Switch Controller 408F makes the destination of the OPN as the destination connection for the loop. Loop traffic is OPN, arbitration and idle primitives. ARBING IDLE When the source switch channel is isolated or when a close connection is seen and there are no other switch channels arbitrating, the state machine 408D returns to the idle state. ARBWON ARBWON Waiting for an open primitive from the source connection, the state machine 408D stays in the arbitration won state. ARBWON OPEN When an open primitive is seen on the source switch channel, the state machine 408D changes to the open state. The Switch Controller 408F makes the destination of the OPN as the destination connection for the loop. Loop traffic is OPN, arbitration and idle primitives. ARBWON ARBING When a close connection is seen and there are other switch channels arbitrating, the state machine 408D changes to the arbitrating state. ARBWON IDLE When the source switch channel is isolated or when a close connection is seen and there are no other switch channels arbitrating, the state machine 408D returns to the idle state. OPEN OPEN While there is an open connection, the state machine 408D stays in the open state. Loop traffic is frames, R_RDYs, idle or arbitration primitives. OPEN ARBING When a close connection is seen and there are other switch channels arbitrating and the previous connection was not a replicate spray, the state machine 408D changes to the arbitrating state. Loop traffic is arbitration primitives. OPEN IDLE When a close connection is seen and there are no other switch channels arbitrating and the previous connection was not a replicate spray, the state machine 408D changes to the idle state. Loop traffic is idle primitives. OPEN CLEAN When a close connection is seen and the previous connection was a replicate spray, the state machine 408D changes to the clean state. Loop traffic is idle or arbitration primitives. OPEN SNDCLS When one of the switch channels is isolated and the CLS was not seen for that connection point, the state machine 408D changes to the send close state (“SNDCLS”). Loop traffic is frames and idle or arbitration primitives. OPEN WTCLS When one of the connection switch channels is isolated and the close was seen for that connection point, the state machine 408D changes to the wait close state (“WTCLS”). Loop traffic is frames and idle or arbitration primitives. CLEAN CLEAN While the switch channels that were part of the replicate spray are retransmitting the close primitive, the state machine 408D stays in the clean state. Loop traffic is idle or arbitration primitives. CLEAN ARBING When the switch channels that were part of the replicate spray have completed retransmitting the close primitive and there is another switch channel arbitrating, the state machine 408D changes to the arbitrating state. Loop traffic is arbitration primitives. CLEAN IDLE When the switch channels that were part of the replicate spray have completed retransmitting the close primitive and there is no other switch channel arbitrating, the state machine 408D changes to the idle state. Loop traffic is idle primitives. CLEAN OPEN When the switch channels that were part of the replicate spray have completed retransmitting the close primitive and there is an open primitive, the state machine 408D changes to the open state. Loop traffic is open, arbitration or idle primitives. SNDCLS SNDCLS Until the correct phase of MsHalfWord and cDataEn occur, the state machine 408D stays in the send close state. Loop traffic is close, idle or arbitration primitives or frames. SNDCLS WTCLS When there is no connection timeout at a next clock edge on the correct phase of MsHalfWord and cDataEn, the state machine 408D changes to the wait close state. Loop traffic is close, idle or arbitration primitives or frames. SNDCLS IDLE When there is a connection timeout at the next clock edge on the correct phase of MsHalfWord and cDataEn, the state machine 408D changes to the idle state. Loop traffic is close, idle or arbitration primitives or frames. WTCLS WTCLS While the connection is completing after one of the connection points is isolated, the state machine 408D stays in the wait close state. Loop traffic is close, idle or arbitration primitives. WTCLS CLEAN When there is a close connection and the previous connection was a replicated spray, the state machine 408D changes to the clean state. Loop traffic is close, idle or arbitration primitives. WTCLS ARBING When there is a close connection and there is another switch channel arbitrating, the state machine 408D changes to the arbitrating state. Loop traffic is close, and arbitration primitives. WTCLS IDLE When there is a close connection and there is no other switch channel arbitrating, the state machine 408D changes to the idle state. Loop traffic is close, and idle primitives. Any IDLE When a connection timeout timer state expires, the state machine 408D except changes to the idle state. The PWRUP timeout indicates that the switch or may be out of sync with the loop LOINIT traffic or that an active switch channel did not follow protocol and needs to be removed as an active connection. Loop traffic could be anything at this time.

Reducing Latency in the “Small Example” Case:

The following illustrates how the present invention minimizes latency in a “small example” case, i.e., where the number of FCD is small, as shown in FIGS. 2 and 3. In FIG. 3 the fibre channel devices are numbered as 301-310 for clarification only, since the fibre channel devices are the same as in FIG. 2. Referring to FIGS. 2 and 3, if FCD #1 wants to send frames to FCD #7, then FCD #1 creates the loop circuit, sends the frames and closes the loop circuit. The following calculations show the difference in latency between traditional and the accelerated implementation. Table III below also provides a comparison between the traditional implementation and the accelerated implementation, according to the present invention:

Arbitration process: In the traditional implementation, the arbitration primitive (“ARB”) passes through all devices on the loop. In the above example, FCD #1 sends the arbitration primitive to FCD #2, which processes this primitive and sends it to FCD #3 and so on until the primitive is sent to FCD #1. The cumulative latency is based on the latency for all devices except #1. If the latency is the same for each device, such as the maximum latency in monitoring mode per the FC-AL standard then the “Total Latency” (latency)(n-1) where n is the number of devices connected to the loop. Thus in the above example Total Latency=(6 transmission word times)(10-1)=54 transmission word times, “word” is a unit for frame (or date) transmission. It is noteworthy that the various adaptive aspects of the present invention are not limited to any particular unit for frame/date transmission.

In the accelerated implementation, according to the present invention, the arbitration primitive is sent to the acceleration device 408 and then looped around. If the arbitrating device is not on host port 404 it takes two re-timing delays to pass from FCD #1 back to FCD #1. If the arbitrating device is on the host port 404, it takes one re-timing delay to pass from FCD #1 back to FCD #1. Hence according to the present invention, the latency will be 16 and 8 transmission word times, respectively, instead of 54 transmission word times in the traditional implementation.

Open process: In the traditional implementation, the open primitive passes through all devices between FCD #1 and FCD #7.

Thus Total Latency=(latency)(m) where m is the number of devices between the two active devices.

In the above example there are 5 devices between the two active devices (FCD #2, #3, #4, #5, #6) and hence, the Total Latency=(6 transmission word times)(5)=30 transmission word times. Thereafter, FCD #7 sends an R_RDY primitive back to FCD #1, which has the same equation for Total Latency.

In the above example there are 3 devices between the two active devices (FCD #8, #9, #10) and the Total Latency=(6 transmission word times)(3)=18 transmission word times. Hence the total latency for the complete open process is 30+18=48 transmission word times.

In the accelerated implementation, according to the present invention, the open primitive is sent to acceleration device 408 and then sent to FCD #7. The total latency is one re-timing delay to pass through the acceleration device 408, which will be 8 transmission word times. Then FCD #7 sends an R_RDY primitive back to FCD #1, which has the same Total Latency, i.e., 8 transmission word times. The total latency for complete open process is 8+8=16 transmission word times, instead of 48 transmission word times in the traditional implementation.

If neither of the active devices is on host port 404, there is another re-timing delay to complete the loop causing the Total Latency to be equal to 24 transmission word times.

Frame process: In the traditional implementation, frames pass through all devices between FCD #1 and FCD #7. The Total Latency=(latency)(m), where m is the number of devices between the two active devices. In the above example there are 5 devices between the two active devices (FCD #2, #3, #4, #5, #6), hence, the Total Latency=(6 transmission word times)(5)=30 transmission word times.

The frames from FCD #7 to FCD #1 have the same equation for Total Latency. In the above example there are 3 devices between the two active devices (FCD #8, #9, #10) and the Total Latency=(6 transmission word times)(3)=18 transmission word times.

In a loop circuit created by an open replicate primitive the frame sent by the source travels the entire loop and then removed by the source device. The Total Latency=(latency)(n−1)=(6 transmission word times)(9)=54 transmission word times.

In the accelerated implementation, according to the present invention, the frames from FCD #1 to FCD #7 are sent to the acceleration device 408 and then sent to FCD #7. The total latency is one re-timing delay to pass through the acceleration device, which is 8 transmission word times. The frames from FCD #7 to FCD #1 have the same Total Latency, i.e. 8 transmission word times. Hence, the total latency is 16 transmission word times, instead of 48 transmission word times in the traditional implementation.

In a loop circuit created by an open replicate primitive the frame sent by the source is sent to all necessary devices at the same time and then returned to the source to be removed. The total latency is two re-timing delays, which is 16 transmission word times, instead of 54 transmission word times in the traditional implementation.

If one of the active devices is not on host port 404 another re-timing delay is added, thus total latency=24 transmission word times.

Close process: The closing of a loop circuit is similar to opening a loop circuit, except that the two active devices can send their close primitives at the same time. In the worst case scenario, the difference in latency between the two implementations is the same as the open process. In the best case scenario, the two active devices have the same number of devices between them on both paths and both devices send their closes at the same time.

In this case for the traditional implementation the Total Latency=(latency)(n/2−1)=(6 transmission word times)(10/2−1)=24 transmission word times.

For the accelerated implementation, according to the present invention, the total latency is two or three re-timing delays (two if the host port has one of the active devices), i.e. 16 or 24 transmission word times. TABLE III Comparison of Latency in a Small Example Case Accelerated Accelerated Implementation/ Implementation/ Host NOT an Latency Type Traditional Host an active port active port Arbitration 54 8 16 Open 48 16 24 Frame FCD #1 to 30 8  8/16 FCD #7 Frame FCD #7 to 18 8 16/8  FCD #1 Frames back and 48 16 24 forth (total) Frame Open 54 16 24 Replicate Close 24 16 24

Reducing Latency in the “Maximum Example” Case:

FC-AL standard allows for a maximum of 127 devices on a loop. All 127 FCDs could be connected to one acceleration device 408 or plural system 307 may be used to operationally/functionally couple 127 devices. In one aspect, 17 FCDs may be coupled to system 307 via acceleration device 408. To get a greater number of devices connected, system 307 be cascaded together such that the cascade port 404A of the first system 307 is connected to the host port 404 of the second system 307 and so on. FIG. 8 shows an example of how plural system 307 may be used to couple 127FCDs (the “Maximum Case” (shown as devices 801-804).

The following provides a comparison (including Table IV) between traditional and the accelerated implementation latency, according to the present invention in the Maximum Example Case.

Arbitration process: In the traditional implementation, the arbitration primitive passes through all devices on the loop. In the above example, FCD #1 sends out the arbitration primitive to FCD #2 that processes this primitive and sends to FCD #3 and so on, until the primitive is sent to FCD #1. The total latency is due to the latency in all devices except #1. If the latency is the same for each device, such as the maximum latency in monitoring mode per the FC-AL standard then, Total Latency=(latency)(n−1) where n is the number of devices connected to the loop. Thus in the above example Total Latency=(6 transmission word times)(127−1)=756 transmission word times.

In the accelerated implementation, the arbitration primitive is sent to the acceleration devices 408 and then looped around. In one aspect, the arbitration primitive is sent to each acceleration device and then looped back. If FCD #1 sends the arbitration primitive then there will be one retiming delay to go through cascade port 404A and then so on through all acceleration devices 408 except the last, which will just take one retiming delay to loop the arbitration primitive back through host port 404. There is a re-timing delay to get the arbitration primitive from the cascade port 404A to host port 404 and so on through plural system 307. Total Latency=(2)(latency)(n−1)+latency=(2)(8 transmission word times)(8)+(8 transmission word times)=136 transmission word times, instead of the traditional 756 transmission word times.

If neither of the active devices is on host port 404 there is another retiming delay to complete the loop causing the Total Latency to be equal to 144 transmission word times.

Open process: In the traditional implementation, the open primitive passes through all devices between FCD #1 and FCD #7. Thus Total Latency=(latency)(m) where m is the number of devices between the two active devices. In the above example there are 5 devices between the two active devices (FCD #2, #3, #4, #5, #6) and the Total Latency=(6 transmission word times)(5)=30 transmission word times. Then FCD #7 will send an R_RDY primitive back to FCD #1, which has the same equation for Total Latency. In the above example there are 120 devices between the two active devices (FCD #8, #9, #10 . . . #127) and the Total Latency=(6 transmission word times)(120)=720 transmission word times. The complete open process is 30+720=750 transmission word times.

In the accelerated implementation, the open primitive is sent to the acceleration device 408 and then sent to FCD #7. The total latency is one retiming delay to pass through the acceleration device 408. This would be 8 transmission word times. Then FCD #7 will send an R_RDY primitive back to FCD #1, which has the Total Latency required to pass through all acceleration devices 408 and loop back to FCD #1, which is 136 transmission word times. The complete open process takes 8+136=144 transmission word times, instead of 750 transmission word times in the traditional implementation.

If neither of the active devices is on host port 404 there is another retiming delay to complete the loop causing the Total Latency to be equal to 152 transmission word times.

Frame process: In the traditional implementation, the frames pass through all devices between FCD #1 and FCD #7. Thus Total Latency=(latency)(m) where m is the number of devices in between the two active devices. In the above example there are 5 devices between the two active devices (FCD #2, #3, #4, #5, #6) and the Total Latency=(6 transmission word times)(5)=30 transmission word times. The frames from FCD #7 to FCD #1 have the same equation for Total Latency. In the above example there are 120 devices between the two active devices (FCD #8, #9, #10 . . . #127) and the Total Latency=(6 transmission word times)(120)=720 transmission word times.

In a loop circuit created by an open replicate primitive the frame sent by the source will travel the entire loop and then be removed by the source device. The Total Latency=(latency)(n-1)=(6 transmission word times)(126)=756 transmission word times.

In the accelerated implementation, the frames are sent to acceleration device 408 and then sent to FCD #7. The total latency is one retiming delay to pass through the acceleration device. This would be 8 transmission word times. The frames from FCD #7 to FCD #1 have the Total Latency of passing through each acceleration device and then looping back, which is 136 transmission word times, according to one aspect of the present invention, instead of 720 transmission word times in the traditional implementation.

In a loop circuit created by an open replicate primitive, the frame sent by the source is sent to all necessary devices at the same time and then returned to the source to be removed. The total latency is one extra retiming delay, which is 144 transmission word times, according to the present invention, instead of 756 transmission word times in the traditional implementation.

If one of the active devices is not on the host port another retiming delay is added, thus total latency=152 transmission word times.

Close process: The closing of a loop circuit is similar to opening a loop circuit, except the two active devices can send their close primitives at the same time. In the worst case scenario, the difference in latency between the two implementations is the same as the open process.

In the best case scenario, the two active devices have the same number of devices between them on both paths and both devices send their “closes” at the same time. In this case for the traditional implementation the Total Latency=(latency)(n/2-1)=(6 transmission word times)(127/2-1)=378 transmission word times.

For the accelerated implementation the total latency is half the total latency of the acceleration devices, 144/2=72 transmission word times, when both devices are sending close at the same time and the devices are half way around the loop from each other. TABLE IV Comparison of Latency in the Maximum Example Case Accelerated Accelerated Implementation/ Implementation/ Host Traditional Host an active NOT an Latency Type implementation port active port Arbitration 756 136 144 Open 750 144 152 Frame FCD #1 30 8 16 to FCD #7 Frame FCD #7 720 136 144 to FCD #1 Frames back 750 144 152 and forth (total) Frame Open 756 152 160 Replicate Close 378 72 80

Although the present invention has been described with reference to specific embodiments, these embodiments are illustrative only and not limiting. Many other applications and embodiments of the present invention will be apparent in light of this disclosure and the following claims. 

1. A fibre channel switch element, comprising: an acceleration device that connects plural fibre channel devices in an arbitrated loop and monitors frames sent during a loop initialization process and creates an AL_PA table selected by each fibre channel device, wherein the AL_PA table is used for port selection; and during an arbitration process sends a benign primitive to non-arbitrating devices.
 2. The switch element of claim 1, wherein during an open process, the acceleration device connects a fibre channel device that wins arbitration to a destination device so that an open primitive can be sent directly to the destination device.
 3. The switch element of claim 1, wherein non-destination devices receive a benign primitive during the open process to maintain proper loop state machine state.
 4. The switch element of claim 1, wherein during an open replicate process, the acceleration device after it receives an open replicate primitive creates a spray pattern for all ports with which a fibre channel device intends to communicate.
 5. The switch element of claim 1, wherein the acceleration device includes a global arbitration module, a state machine module, and a matrix for connecting plural fibre channel devices.
 6. The switch element of claim 5, wherein only one state machine is used for describing an arbitrated loop state.
 7. An acceleration device used by a fibre channel switch element, comprising: a global arbitration module, a state machine module, and a matrix for connecting plural fibre channel devices; wherein the acceleration device connects plural fibre channel devices in an arbitrated loop and monitors frames sent during a loop initialization process and creates an AL_PA table selected by each fibre channel device, wherein the AL_PA table is used for port selection; and during an arbitration process sends a benign primitive to non-arbitrating devices.
 8. The acceleration device of claim 7, wherein during an open process, the acceleration device connects a fibre channel device that wins arbitration to a destination device so that an open primitive can be sent directly to the destination device.
 9. The acceleration device of claim 8, wherein non-destination devices receive a benign primitive during the open process to maintain proper loop state machine state.
 10. The acceleration device of claim 7, wherein during an open replicate process, the acceleration device after it receives an open replicate primitive creates a spray pattern for all ports with which a fibre channel device intends to communicate.
 11. The switch element of claim 7, wherein only one state machine is used for describing an arbitrated loop state.
 12. A method for accelerating traffic in a fibre channel arbitrated loop topology having a fibre channel switch element with an acceleration device, comprising: monitoring fibre channel frames during a loop initialization process; creating an AL_PA table for fibre channel devices connected in the arbitrated loop and using the AL_PA table for identifying ports.
 13. The method of claim 12, further comprising: sending benign primitives to non-arbitrating devices during an arbitration process.
 14. The method of claim 12, further comprising: connecting a fibre channel device that sends an OPEN primitive to a destination port; and sending a benign primitive to non-destination device connected in the arbitrated loop.
 15. The method of claim 14, further comprising: creating a spray pattern after receiving an open replicate primitive from a fibre channel device; and sending frames to plural destination ports at the same time. 